clang-tools-extra/clangd/ConfigCompile.cpp - llvm-project - Git at Google

 //===--- ConfigCompile.cpp - Translating Fragments into Config ------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//
 //
 // Fragments are applied to Configs in two steps:
 //
 // 1. (When the fragment is first loaded)
 //    FragmentCompiler::compile() traverses the Fragment and creates
 //    function objects that know how to apply the configuration.
 // 2. (Every time a config is required)
 //    CompiledFragment() executes these functions to populate the Config.
 //
 // Work could be split between these steps in different ways. We try to
 // do as much work as possible in the first step. For example, regexes are
 // compiled in stage 1 and captured by the apply function. This is because:
 //
 //  - it's more efficient, as the work done in stage 1 must only be done once
 //  - problems can be reported in stage 1, in stage 2 we must silently recover
 //
 //===----------------------------------------------------------------------===//

 #include "CompileCommands.h"
 #include "Config.h"
 #include "ConfigFragment.h"
 #include "support/Logger.h"
 #include "support/Trace.h"
 #include "llvm/ADT/STLExtras.h"
 #include "llvm/ADT/StringRef.h"
 #include "llvm/ADT/StringSwitch.h"
 #include "llvm/Support/Regex.h"
 #include "llvm/Support/SMLoc.h"
 #include "llvm/Support/SourceMgr.h"

 namespace clang {
 namespace clangd {
 namespace config {
 namespace {

 struct CompiledFragmentImpl {
   // The independent conditions to check before using settings from this config.
   // The following fragment has *two* conditions:
   //   If: { Platform: [mac, linux], PathMatch: foo/.* }
   // All of them must be satisfied: the platform and path conditions are ANDed.
   // The OR logic for the platform condition is implemented inside the function.
   std::vector<llvm::unique_function<bool(const Params &) const>> Conditions;
   // Mutations that this fragment will apply to the configuration.
   // These are invoked only if the conditions are satisfied.
   std::vector<llvm::unique_function<void(Config &) const>> Apply;

   bool operator()(const Params &P, Config &C) const {
     for (const auto &C : Conditions) {
       if (!C(P)) {
         dlog("Config fragment {0}: condition not met", this);
         return false;
       }
     }
     dlog("Config fragment {0}: applying {1} rules", this, Apply.size());
     for (const auto &A : Apply)
       A(C);
     return true;
   }
 };

 // Wrapper around condition compile() functions to reduce arg-passing.
 struct FragmentCompiler {
   CompiledFragmentImpl &Out;
   DiagnosticCallback Diagnostic;
   llvm::SourceMgr *SourceMgr;

   llvm::Optional<llvm::Regex> compileRegex(const Located<std::string> &Text) {
     std::string Anchored = "^(" + *Text + ")$";
     llvm::Regex Result(Anchored);
     std::string RegexError;
     if (!Result.isValid(RegexError)) {
       diag(Error, "Invalid regex " + Anchored + ": " + RegexError, Text.Range);
       return llvm::None;
     }
     return Result;
   }

   // Helper with similar API to StringSwitch, for parsing enum values.
   template <typename T> class EnumSwitch {
     FragmentCompiler &Outer;
     llvm::StringRef EnumName;
     const Located<std::string> &Input;
     llvm::Optional<T> Result;
     llvm::SmallVector<llvm::StringLiteral, 8> ValidValues;

   public:
     EnumSwitch(llvm::StringRef EnumName, const Located<std::string> &In,
                FragmentCompiler &Outer)
         : Outer(Outer), EnumName(EnumName), Input(In) {}

     EnumSwitch &map(llvm::StringLiteral Name, T Value) {
       assert(!llvm::is_contained(ValidValues, Name) && "Duplicate value!");
       ValidValues.push_back(Name);
       if (!Result && *Input == Name)
         Result = Value;
       return *this;
     }

     llvm::Optional<T> value() {
       if (!Result)
         Outer.diag(
             Warning,
             llvm::formatv("Invalid {0} value '{1}'. Valid values are {2}.",
                           EnumName, *Input, llvm::join(ValidValues, ", "))
                 .str(),
             Input.Range);
       return Result;
     };
   };

   // Attempt to parse a specified string into an enum.
   // Yields llvm::None and produces a diagnostic on failure.
   //
   // Optional<T> Value = compileEnum<En>("Foo", Frag.Foo)
   //    .map("Foo", Enum::Foo)
   //    .map("Bar", Enum::Bar)
   //    .value();
   template <typename T>
   EnumSwitch<T> compileEnum(llvm::StringRef EnumName,
                             const Located<std::string> &In) {
     return EnumSwitch<T>(EnumName, In, *this);
   }

   void compile(Fragment &&F) {
     compile(std::move(F.If));
     compile(std::move(F.CompileFlags));
     compile(std::move(F.Index));
   }

   void compile(Fragment::IfBlock &&F) {
     if (F.HasUnrecognizedCondition)
       Out.Conditions.push_back([&](const Params &) { return false; });

     auto PathMatch = std::make_unique<std::vector<llvm::Regex>>();
     for (auto &Entry : F.PathMatch) {
       if (auto RE = compileRegex(Entry))
         PathMatch->push_back(std::move(*RE));
     }
     if (!PathMatch->empty()) {
       Out.Conditions.push_back(
           [PathMatch(std::move(PathMatch))](const Params &P) {
             if (P.Path.empty())
               return false;
             return llvm::any_of(*PathMatch, [&](const llvm::Regex &RE) {
               return RE.match(P.Path);
             });
           });
     }

     auto PathExclude = std::make_unique<std::vector<llvm::Regex>>();
     for (auto &Entry : F.PathExclude) {
       if (auto RE = compileRegex(Entry))
         PathExclude->push_back(std::move(*RE));
     }
     if (!PathExclude->empty()) {
       Out.Conditions.push_back(
           [PathExclude(std::move(PathExclude))](const Params &P) {
             if (P.Path.empty())
               return false;
             return llvm::none_of(*PathExclude, [&](const llvm::Regex &RE) {
               return RE.match(P.Path);
             });
           });
     }
   }

   void compile(Fragment::CompileFlagsBlock &&F) {
     if (!F.Remove.empty()) {
       auto Remove = std::make_shared<ArgStripper>();
       for (auto &A : F.Remove)
         Remove->strip(*A);
       Out.Apply.push_back([Remove(std::shared_ptr<const ArgStripper>(
                               std::move(Remove)))](Config &C) {
         C.CompileFlags.Edits.push_back(
             [Remove](std::vector<std::string> &Args) {
               Remove->process(Args);
             });
       });
     }

     if (!F.Add.empty()) {
       std::vector<std::string> Add;
       for (auto &A : F.Add)
         Add.push_back(std::move(*A));
       Out.Apply.push_back([Add(std::move(Add))](Config &C) {
         C.CompileFlags.Edits.push_back([Add](std::vector<std::string> &Args) {
           Args.insert(Args.end(), Add.begin(), Add.end());
         });
       });
     }
   }

   void compile(Fragment::IndexBlock &&F) {
     if (F.Background) {
       if (auto Val = compileEnum<Config::BackgroundPolicy>("Background",
                                                            **F.Background)
                          .map("Build", Config::BackgroundPolicy::Build)
                          .map("Skip", Config::BackgroundPolicy::Skip)
                          .value())
         Out.Apply.push_back([Val](Config &C) { C.Index.Background = *Val; });
     }
   }

   constexpr static llvm::SourceMgr::DiagKind Error = llvm::SourceMgr::DK_Error;
   constexpr static llvm::SourceMgr::DiagKind Warning =
       llvm::SourceMgr::DK_Warning;
   void diag(llvm::SourceMgr::DiagKind Kind, llvm::StringRef Message,
             llvm::SMRange Range) {
     if (Range.isValid() && SourceMgr != nullptr)
       Diagnostic(SourceMgr->GetMessage(Range.Start, Kind, Message, Range));
     else
       Diagnostic(llvm::SMDiagnostic("", Kind, Message));
   }
 };

 } // namespace

 CompiledFragment Fragment::compile(DiagnosticCallback D) && {
   llvm::StringRef ConfigFile = "<unknown>";
   std::pair<unsigned, unsigned> LineCol = {0, 0};
   if (auto *SM = Source.Manager.get()) {
     unsigned BufID = SM->getMainFileID();
     LineCol = SM->getLineAndColumn(Source.Location, BufID);
     ConfigFile = SM->getBufferInfo(BufID).Buffer->getBufferIdentifier();
   }
   trace::Span Tracer("ConfigCompile");
   SPAN_ATTACH(Tracer, "ConfigFile", ConfigFile);
   auto Result = std::make_shared<CompiledFragmentImpl>();
   vlog("Config fragment: compiling {0}:{1} -> {2}", ConfigFile, LineCol.first,
        Result.get());

   FragmentCompiler{*Result, D, Source.Manager.get()}.compile(std::move(*this));
   // Return as cheaply-copyable wrapper.
   return [Result(std::move(Result))](const Params &P, Config &C) {
     return (*Result)(P, C);
   };
 }

 } // namespace config
 } // namespace clangd
 } // namespace clang
	//===--- ConfigCompile.cpp - Translating Fragments into Config ------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//
	//
	// Fragments are applied to Configs in two steps:
	//
	// 1. (When the fragment is first loaded)
	// FragmentCompiler::compile() traverses the Fragment and creates
	// function objects that know how to apply the configuration.
	// 2. (Every time a config is required)
	// CompiledFragment() executes these functions to populate the Config.
	//
	// Work could be split between these steps in different ways. We try to
	// do as much work as possible in the first step. For example, regexes are
	// compiled in stage 1 and captured by the apply function. This is because:
	//
	// - it's more efficient, as the work done in stage 1 must only be done once
	// - problems can be reported in stage 1, in stage 2 we must silently recover
	//
	//===----------------------------------------------------------------------===//

	#include "CompileCommands.h"
	#include "Config.h"
	#include "ConfigFragment.h"
	#include "support/Logger.h"
	#include "support/Trace.h"
	#include "llvm/ADT/STLExtras.h"
	#include "llvm/ADT/StringRef.h"
	#include "llvm/ADT/StringSwitch.h"
	#include "llvm/Support/Regex.h"
	#include "llvm/Support/SMLoc.h"
	#include "llvm/Support/SourceMgr.h"

	namespace clang {
	namespace clangd {
	namespace config {
	namespace {

	struct CompiledFragmentImpl {
	// The independent conditions to check before using settings from this config.
	// The following fragment has two conditions:
	// If: { Platform: [mac, linux], PathMatch: foo/.* }
	// All of them must be satisfied: the platform and path conditions are ANDed.
	// The OR logic for the platform condition is implemented inside the function.
	std::vector<llvm::unique_function<bool(const Params &) const>> Conditions;
	// Mutations that this fragment will apply to the configuration.
	// These are invoked only if the conditions are satisfied.
	std::vector<llvm::unique_function<void(Config &) const>> Apply;

	bool operator()(const Params &P, Config &C) const {
	for (const auto &C : Conditions) {
	if (!C(P)) {
	dlog("Config fragment {0}: condition not met", this);
	return false;
	}
	}
	dlog("Config fragment {0}: applying {1} rules", this, Apply.size());
	for (const auto &A : Apply)
	A(C);
	return true;
	}
	};

	// Wrapper around condition compile() functions to reduce arg-passing.
	struct FragmentCompiler {
	CompiledFragmentImpl &Out;
	DiagnosticCallback Diagnostic;
	llvm::SourceMgr *SourceMgr;

	llvm::Optional<llvm::Regex> compileRegex(const Located<std::string> &Text) {
	std::string Anchored = "^(" + *Text + ")$";
	llvm::Regex Result(Anchored);
	std::string RegexError;
	if (!Result.isValid(RegexError)) {
	diag(Error, "Invalid regex " + Anchored + ": " + RegexError, Text.Range);
	return llvm::None;
	}
	return Result;
	}

	// Helper with similar API to StringSwitch, for parsing enum values.
	template <typename T> class EnumSwitch {
	FragmentCompiler &Outer;
	llvm::StringRef EnumName;
	const Located<std::string> &Input;
	llvm::Optional<T> Result;
	llvm::SmallVector<llvm::StringLiteral, 8> ValidValues;

	public:
	EnumSwitch(llvm::StringRef EnumName, const Located<std::string> &In,
	FragmentCompiler &Outer)
	: Outer(Outer), EnumName(EnumName), Input(In) {}

	EnumSwitch &map(llvm::StringLiteral Name, T Value) {
	assert(!llvm::is_contained(ValidValues, Name) && "Duplicate value!");
	ValidValues.push_back(Name);
	if (!Result && *Input == Name)
	Result = Value;
	return *this;
	}

	llvm::Optional<T> value() {
	if (!Result)
	Outer.diag(
	Warning,
	llvm::formatv("Invalid {0} value '{1}'. Valid values are {2}.",
	EnumName, *Input, llvm::join(ValidValues, ", "))
	.str(),
	Input.Range);
	return Result;
	};
	};

	// Attempt to parse a specified string into an enum.
	// Yields llvm::None and produces a diagnostic on failure.
	//
	// Optional<T> Value = compileEnum<En>("Foo", Frag.Foo)
	// .map("Foo", Enum::Foo)
	// .map("Bar", Enum::Bar)
	// .value();
	template <typename T>
	EnumSwitch<T> compileEnum(llvm::StringRef EnumName,
	const Located<std::string> &In) {
	return EnumSwitch<T>(EnumName, In, *this);
	}

	void compile(Fragment &&F) {
	compile(std::move(F.If));
	compile(std::move(F.CompileFlags));
	compile(std::move(F.Index));
	}

	void compile(Fragment::IfBlock &&F) {
	if (F.HasUnrecognizedCondition)
	Out.Conditions.push_back([&](const Params &) { return false; });

	auto PathMatch = std::make_unique<std::vector<llvm::Regex>>();
	for (auto &Entry : F.PathMatch) {
	if (auto RE = compileRegex(Entry))
	PathMatch->push_back(std::move(*RE));
	}
	if (!PathMatch->empty()) {
	Out.Conditions.push_back(
	[PathMatch(std::move(PathMatch))](const Params &P) {
	if (P.Path.empty())
	return false;
	return llvm::any_of(*PathMatch, [&](const llvm::Regex &RE) {
	return RE.match(P.Path);
	});
	});
	}

	auto PathExclude = std::make_unique<std::vector<llvm::Regex>>();
	for (auto &Entry : F.PathExclude) {
	if (auto RE = compileRegex(Entry))
	PathExclude->push_back(std::move(*RE));
	}
	if (!PathExclude->empty()) {
	Out.Conditions.push_back(
	[PathExclude(std::move(PathExclude))](const Params &P) {
	if (P.Path.empty())
	return false;
	return llvm::none_of(*PathExclude, [&](const llvm::Regex &RE) {
	return RE.match(P.Path);
	});
	});
	}
	}

	void compile(Fragment::CompileFlagsBlock &&F) {
	if (!F.Remove.empty()) {
	auto Remove = std::make_shared<ArgStripper>();
	for (auto &A : F.Remove)
	Remove->strip(*A);
	Out.Apply.push_back([Remove(std::shared_ptr<const ArgStripper>(
	std::move(Remove)))](Config &C) {
	C.CompileFlags.Edits.push_back(
	[Remove](std::vector<std::string> &Args) {
	Remove->process(Args);
	});
	});
	}

	if (!F.Add.empty()) {
	std::vector<std::string> Add;
	for (auto &A : F.Add)
	Add.push_back(std::move(*A));
	Out.Apply.push_back([Add(std::move(Add))](Config &C) {
	C.CompileFlags.Edits.push_back([Add](std::vector<std::string> &Args) {
	Args.insert(Args.end(), Add.begin(), Add.end());
	});
	});
	}
	}

	void compile(Fragment::IndexBlock &&F) {
	if (F.Background) {
	if (auto Val = compileEnum<Config::BackgroundPolicy>("Background",
	**F.Background)
	.map("Build", Config::BackgroundPolicy::Build)
	.map("Skip", Config::BackgroundPolicy::Skip)
	.value())
	Out.Apply.push_back([Val](Config &C) { C.Index.Background = *Val; });
	}
	}

	constexpr static llvm::SourceMgr::DiagKind Error = llvm::SourceMgr::DK_Error;
	constexpr static llvm::SourceMgr::DiagKind Warning =
	llvm::SourceMgr::DK_Warning;
	void diag(llvm::SourceMgr::DiagKind Kind, llvm::StringRef Message,
	llvm::SMRange Range) {
	if (Range.isValid() && SourceMgr != nullptr)
	Diagnostic(SourceMgr->GetMessage(Range.Start, Kind, Message, Range));
	else
	Diagnostic(llvm::SMDiagnostic("", Kind, Message));
	}
	};

	} // namespace

	CompiledFragment Fragment::compile(DiagnosticCallback D) && {
	llvm::StringRef ConfigFile = "<unknown>";
	std::pair<unsigned, unsigned> LineCol = {0, 0};
	if (auto *SM = Source.Manager.get()) {
	unsigned BufID = SM->getMainFileID();
	LineCol = SM->getLineAndColumn(Source.Location, BufID);
	ConfigFile = SM->getBufferInfo(BufID).Buffer->getBufferIdentifier();
	}
	trace::Span Tracer("ConfigCompile");
	SPAN_ATTACH(Tracer, "ConfigFile", ConfigFile);
	auto Result = std::make_shared<CompiledFragmentImpl>();
	vlog("Config fragment: compiling {0}:{1} -> {2}", ConfigFile, LineCol.first,
	Result.get());

	FragmentCompiler{Result, D, Source.Manager.get()}.compile(std::move(this));
	// Return as cheaply-copyable wrapper.
	return [Result(std::move(Result))](const Params &P, Config &C) {
	return (*Result)(P, C);
	};
	}

	} // namespace config
	} // namespace clangd
	} // namespace clang